Assemblies; components and filter features thereof; and, methods of use and assembly

ABSTRACT

An air cleaner assembly is disclosed, along with related methods. In one aspect, the air cleaner assembly has a housing including a housing body and a removable cover that together define an interior volume for holding a filter cartridge. The housing body can include a first plurality of lugs, wherein each of the first plurality of lugs has a first engagement surface disposed at a first angle that is oblique to a rotational plane of the cover. A second plurality of lugs can be provided on the cover, wherein each of the second plurality of lugs has a second engagement surface disposed at the first angle. A lock mechanism can also be provided that is disposed on the cover, wherein the lock mechanism includes a lock member axially movable between a locked position and an unlocked position to selectively secure the cover to the housing body.

RELATED APPLICATIONS

This application is a continuation of application Ser. No. 15/192,272, filed Jun. 24, 2016, which claims the benefit of provisional application Ser. No. 62/184,567, filed Jun. 25, 2015, which applications are incorporated herein by reference in their entirety.

FIELD OF THE DISCLOSURE

The present disclosure relates to filter assemblies, for example air cleaner assemblies, and components and features thereof, and methods of assembly and use. The filter assemblies comprise a housing having a removable and replaceable filter cartridge therein. The filter cartridge is optionally configured with a housing seal arrangement, to advantage. Various features of filter housings and/or the cartridges are described, including features directed to securing the housing to a removable cover, which can provide for advantage. Methods of assembly and use are described.

BACKGROUND

Air or other gas filtering is desirable in a number of systems. A typical application is in the filtration of intake air to internal combustion engines. Another is in the filtration of crankcase ventilation filter assemblies. Typically, such systems comprise filter assemblies having a serviceable filter cartridge therein. After a period of use, filter media within a filter housing requires servicing, either through cleaning or complete replacement. Typically, for an air cleaner or crankcase ventilation filter assembly used with an internal combustion engine, for example on a vehicle, the filter media is contained in a removable and replaceable, i.e. serviceable, component, typically referred as a filter element or cartridge. The filter cartridge is configured to be removably sealed within the air cleaner, in use. Improvements in filter arrangements relating to assembly, serviceability, use are desirable.

SUMMARY

Filter assemblies (such as air cleaner assemblies or crankcase ventilation filter assemblies) components therefor; and, features thereof are described. Also described are methods of assembly and use. The filter assemblies generally comprise a housing assembly having a filter cartridge removably positioned therein. The housing assembly includes a housing body and a removable cover which can be secured together in an axial direction through the interaction of respective lugs located on the housing body and on the cover.

The lugs on the housing body can be engaged with the lugs on the cover by first axially displacing the cover towards the housing body along the longitudinal axis of the housing assembly until the lugs on the cover move past the lugs on the housing body. At this point, the cover can be rotated in a direction C about the longitudinal axis such that a ramped engagement surface of each lug is brought into engagement with a ramped engagement surface of a corresponding lug. As this rotation occurs, the respective ramped engagement surfaces will function to draw the cover towards the housing body in an axial direction until a stop surface on the cover comes into contact with an open end of the housing body, at which point further rotation is prevented. To hold the cover in this position relative to the housing body, a lock mechanism can be provided which includes a lock member that can be inserted between two adjacent lugs such that the cover cannot be rotated in the reverse direction to disengage the lugs such that the cover can be removed from the housing body.

In one example, an air cleaner is disclosed having a housing including a housing body and a removable cover that together define an interior volume for holding a filter cartridge. The removable cover can be rotatable with respect to the housing body along a plane of rotation. The housing body can include a first plurality of lugs, wherein each of the first plurality of lugs has a first engagement surface disposed at a first angle that is oblique to the plane of rotation. A second plurality of lugs can be provided on the cover, wherein each of the second plurality of lugs has a second engagement surface disposed at the first angle. A lock mechanism can also be provided that is disposed on the cover, wherein the lock mechanism includes a lock member axially movable between a locked position and an unlocked position.

In one aspect, the cover is positionable between a secured position and an unsecured position. In the secured position, at least one of the first engagement surfaces of the first plurality of lugs is in overlapping contact with at least one of the second engagement surfaces of the second plurality of lugs such that the cover is prevented from rotating in a first direction along the plane of rotation and wherein the lock member extends between two of the first plurality of lugs to prevent the cover from being rotated in a second direction opposite the first direction. In the unsecured position, the lock member is removed from between the two of the first plurality of ramped lugs such that the cover can be rotated in the second direction.

The air cleaner assembly can also be configured such that each of the first plurality of lugs includes a guide surface disposed at a second angle that is oblique to the plane of rotation, wherein the guide surface is for guiding the lock member towards a first side of one of the first plurality of lugs as the lock member is being displaced between two of the first plurality of lugs. A guide member extending from the guide surface of each of the first plurality of lugs can also be provide and can act to constrain the movement of the lock member along the guide surface.

There is no specific requirement that an air cleaner assembly, component therefor, or feature thereof include all of the detail characterized herein, to obtain some advantage according to the present disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic side view of an air cleaner assembly having features in accordance with the present disclosure.

FIG. 2 is a schematic top view of the air cleaner assembly shown in FIG. 1.

FIG. 3 is a schematic exploded perspective view of the air cleaner assembly shown in FIG. 1.

FIG. 4 is a schematic perspective view of a primary filter cartridge of the air cleaner assembly shown in FIG. 1.

FIG. 5 is schematic cross-sectional view of the primary filter cartridge shown in FIG. 4.

FIG. 6 is a schematic side view of a secondary filter cartridge of the air cleaner assembly shown in FIG. 1.

FIG. 7 is schematic cross-sectional view of the secondary filter cartridge shown in FIG. 4.

FIG. 8 is a schematic partially exploded perspective view of the air cleaner assembly shown in FIG. 1 with the cover removed from the housing body.

FIG. 9 is a schematic elevational view of a lug of the cover being aligned with a lug of the housing body of the air cleaner assembly shown in FIG. 1.

FIG. 10 is a schematic elevational view of the lugs shown in FIG. 9 in an engaged position.

FIG. 11 is a schematic side view of the housing body of the air cleaner assembly shown in FIG. 1.

FIG. 12 is an enlarged schematic view of a portion of the housing body of the air cleaner assembly shown in FIG. 1, taken along the section line 12-12 shown in FIG. 11.

FIG. 13 is a schematic cross-sectional view of the cover of the air cleaner assembly shown in FIG. 1, taken along the line 13-13 in FIG. 23.

FIG. 14 is a schematic side view of the air cleaner assembly shown in FIG. 1, with a cut-a-way portion showing the lock mechanism in an unlocked position.

FIG. 15 is a schematic side view of the air cleaner assembly shown in FIG. 1, with a cut-a-way portion showing the lock mechanism in a locked position.

FIG. 16 is a front view of the lock mechanism of the air cleaner assembly shown in FIG. 1.

FIG. 17 is a perspective view of the lock mechanism shown in FIG. 16.

FIG. 18 is an enlarged portion of the lock mechanism shown at FIG. 16, as indicated at FIG. 16.

FIG. 19 is a side view of the lock mechanism shown in FIG. 16.

FIG. 20 is a partially exploded view of the cover and the lock mechanism shown in FIG. 16.

FIG. 21 is a top view of the cover and lock mechanism shown in FIG. 16.

FIG. 22 is an enlarged portion of the cover and lock mechanism shown in FIG. 16, taken along the line 21-22 in FIG. 21.

FIG. 23 is a bottom view of the cover of the air cleaner assembly shown in FIG. 1, with the lock assembly removed.

FIG. 24 is a top view of the cover of the air cleaner assembly shown in FIG. 1, with the lock assembly removed.

FIG. 25 is an enlarged top view of a portion of the cover of the air cleaner assembly shown in FIG. 1, as indicated at FIG. 24.

FIG. 26 is a cross-sectional view of a portion of the cover of the air cleaner assembly shown in FIG. 1, as indicated at line 26-26 at FIG. 23.

FIG. 27 is a cross-sectional view of a portion of the cover of the air cleaner assembly shown in FIG. 1, as indicated at line 27-27 at FIG. 24.

FIG. 28 is an enlarged elevational view of the inside of the cover shown in FIG. 13.

FIG. 29 is a cross-sectional view of the cover shown in FIG. 28, taken along the lines 29-29.

FIG. 30 is a schematic side view of the air cleaner assembly shown in FIG. 1, with a cut-a-way portion showing the lock mechanism in a locked position and showing a modified lug configuration.

FIG. 31 is a schematic side view of the air cleaner assembly shown in FIG. 1, with a cut-a-way portion showing the lock mechanism in a locked position and showing a modified lug configuration.

DETAILED DESCRIPTION

Herein, an example filter assemblies, features and components therefor are described and depicted. A variety of specific features and components are characterized in detail. Many can be applied to provide advantage. There is no specific requirement that the various individual features and components be applied in an overall assembly with all of the features and characteristics described, however, in order to provide for some benefit in accord with the present disclosure.

Referring to FIG. 1, an air cleaner assembly 100 is shown. In one aspect, the air cleaner assembly 100 includes a housing assembly 102 including a housing body 104 and a removable cover 106. When the cover 106 is attached to the housing body 104, the cover 106 and housing body 104 define an interior volume 108. The air cleaner assembly 100 is also shown as including a primary filter cartridge 200 and a secondary filter cartridge 220, both of which are disposed within the interior volume 108 of the air cleaner assembly 100.

As shown, the primary filter cartridge 200 includes a closed end cap 202 and an open end cap 204, between which filter media 206 extends. In one example, the end caps 202, 204 are formed from a molded polyurethane material. As shown, filter media 206 is pleated cellulosic media arranged into a tubular, cylindrical shape defining an interior 208 and an exterior side 210. A support tube 212, which may formed from a plastic or metal material, is provided at the interior 208 of the media 206 to support the media 206. Other configurations for the primary filter cartridge 200 are possible without departing from the concepts presented herein. An example primary filter cartridge usable with the air cleaner assembly 100 disclosed herein is fully shown and described in U.S. Pat. No. 8,864,866, issued on Oct. 21, 2014, the entirety of which is incorporated by reference herein.

As shown, the secondary filter cartridge 220 includes a closed end cap 222 and an open end cap 224, between which filter media 226 extends. In one example, the end caps 222, 224 are formed from a molded polyurethane material. As shown, filter media 226 is a synthetic non-pleated fabric media arranged into a tubular, cylindrical shape defining an interior 228 and an exterior side 230. An inner liner 232 is provided at the interior 208 of the media 206 and an outer liner 234 is provide at the exterior side 230 of the media 206 to support the media 206. The liners 232, 234 may be formed from a plastic or metal material. Other configurations for the secondary filter cartridge 220 are possible without departing from the concepts presented herein. An example secondary filter cartridge usable with the air cleaner assembly 100 disclosed herein is fully shown and described in U.S. Pat. No. 8,864,866.

The housing body 104 is further shown as having an air inlet 110 and a rotatable air outlet 112. As configured, the secondary filter cartridge 220 is mounted within the housing body 104 such that the open end cap 224 seals to a portion of the housing body 104 to place the interior 228 of the secondary filter cartridge 220 in fluid tight communication with the air outlet 112. In the embodiment shown, the open end cap 224 forms an outwardly directed radial seal against a portion of the housing. The primary filter cartridge 200 is mounted within the housing body 104 and over the secondary filter cartridge 220 such that the secondary filter cartridge 220 is received within the interior 208 of the primary filter cartridge 200. The open end cap 204 of the primary filter cartridge 200 seals to a portion of the housing body 104 such that the interior 208 of the primary filter cartridge 200 is in fluid tight communication with the secondary filter cartridge interior 208. In operation, with the cover 106 attached to the housing body 104, unfiltered air flows into the air inlet 110 and passes through the media 206 from the main filter cartridge exterior side 210 to the interior 208. The air then flows through the secondary filter cartridge media 226 from the exterior side 230 to the interior 228, where the fully filtered air the passes through the outlet 112 and to connected equipment, such as the air intake system of an internal combustion engine. The cover 106 can be provided with a dust ejection valve 114 to discharge accumulated particulates from the interior volume 108 of the housing assembly 102.

To secure the cover 106 to the housing body 104, a twist-lock arrangement 120 is provided in which a plurality of lugs 122 are provided on a wall 129 of the housing body 104 that engage with a plurality of ramped lugs 124 on the cover 106. By use of the term “lug” it is meant to include any type of protrusion that extends from a sidewall. Examples of protrusions within the meaning of the term lug are protrusions having a geometrically or irregularly shaped cross-section, protrusions configured to provide a single point of contact, protrusions having an elongated surface, protrusions having a continuous or discontinuous surface, and groups of independently formed protrusions. As presented, the lugs 122, 124 are integrally molded projections extending radially outwardly from the housing body 104 and extending radially inwardly from the cover 106, respectively.

In the particular embodiment shown, twelve lugs 122 are provided while six lugs 124 are provided. However, it is noted that the number of lugs 122 may be equal to or less than the number of lugs 124. Other quantities of lugs 122, 124 may be provided, such as one lug 122, 124, two lugs 122, 124, four lugs 122, 124, and six lugs 122, 124. In one example, a single lug 122 is provided on the housing body 104 and a single luge 124 is provided on the cover 106. In such a case, an additional alignment feature may be provided to ensure that the cover 106 is properly oriented with respect to the housing body 104 such that the single lugs 122, 124 will be properly engaged upon rotation of the cover 106. In one example, a single lug 124 is provided on the cover 106 while two or more lugs 122 are provided on the housing body. Providing two or more lugs 124 on the cover 106 can be advantageous over the previously described example in which only one lug 122 and one lug 124 are provided. For example, providing two or more lugs 124 on the cover 106 increases the number of possible locking positions of the cover 106 onto the housing body 104. To illustrate, the lug 124 can engage with either the first lug 122 or the second lug 122 on the housing body, or any other lug 122 additionally provided on the housing body 104. Additionally, the maximum rotation of the cover 106 on the housing body 104 required to lock the cover 106 to the housing body 104 is decreased as the number of lugs 122 are increased. To illustrate, the cover 106 may be required to rotate almost 360 (minus the length of the lug 12) in order to bring the cover lug 124 into engagement with a lug 122 when only one lug 122 is provided. However, providing two lugs 124 reduces the maximum rotation to less than 180 degrees, providing three lugs reduces the maximum rotation to less than 120 degrees, and so on. In one example, a single lug 122 is provided on the housing body while two or more lugs 124 are provided on the cover 106. Including two or more lugs 124 for the single lug 122 can provide the same advantages as previously described for the example in which a single lug 124 and two or more lugs 122 are provided.

To install the cover 106 onto the housing body 104, the cover 106 is aligned with longitudinal axis X of the housing body 104 and is oriented such that lugs 124 are aligned between the lugs 122, as shown at FIG. 8. The lugs 122 and 124 necessarily lie along a common or near-common diameter to enable the lugs 122, 124 to engage with each other. As such, the lugs 124 must be rotationally aligned between the lugs 122 in order for the cover 106 to be fully installed onto the housing body 104. Once aligned, the cover 106 can then axially displaced towards the housing body 104 along the axis X in a direction A until ramped engagement surfaces 124 a of the lugs 124 move partially past ramped engagement surfaces 122 a of the lugs 122. This position can be seen at the schematic provided at FIG. 9 where it can be seen that the lug 124 has been at partially displaced below the lug 122.

By use of the terms “ramped” in relation to a surface or engagement surface, it is meant to indicate a surface that is disposed at an oblique angle relative to the plane of rotation R. As the longitudinal axis X is at a right angle to the plane of rotation, the ramped surface is also disposed at an oblique angle to the axis X. The ramped surface may be a planar surface, a curved surface, a smooth surface free of protrusions and indentations, or a surface including protrusions and/or indentations. In the embodiment shown, the ramped engagement surfaces 122 a, 124 a are smooth, planar surfaces. Where a ramped surface is referred to as an engagement surface in configurations where at least a portion of the surface is configured to come into contact with another surface. For example, ramped engagement surface 124 a is configured to come into direct contact with a ramped engagement surface 122 a. As shown, each of the ramped engagement surfaces 122 a, 124 a of the lugs 122, 124 is disposed at a first angle a relative to the plane of rotation R. As such, the ramped surface 122 a is parallel to the ramped surface 124 a. In one example, the first angle is about 10 degrees. However, other oblique angles may also be utilized without departing from the concepts presented herein. The angle of the engagement surface 122 a can also be a different angle than that of the engagement surface 124 a, although a single or reduced point of contact between the lugs 122, 124 might be expected to occur rather than having the majority of the lengths of the surfaces 122 a, 124 a in contact with each other.

At this point, the cover 106 can be rotated in a direction C about the longitudinal axis X and along a plane of rotation R such that the ramped engagement surface 124 a of each lug 124 is brought into engagement with the ramped engagement surface 122 a of a corresponding lug 122, as shown at FIG. 10. As this rotation occurs, the ramped engagement surfaces 122 a, 124 a will function to draw the cover 106 towards the housing body 104 until a stop surface or shoulder 126 on the cover 106 comes into contact with the open end 128 of the housing body 104 at which point further rotation is prevented. In some embodiments, the length of the primary filter cartridge 200 is such that a compressive force is required to engage the shoulder 126 with the open end 128. In such instances, this compressive force increases the friction between the surfaces 122 a, 124 a and can aid in maintaining engagement between the lugs 122, 124. Additionally, where such a compression configuration exists, the air cleaner assembly 100 may be constructed such that the open end 128 and the shoulder 126 do not engage when the cover 106 is fully tightened onto the housing body 104.

To hold the cover 106 in this closed position relative to the housing body 104, a lock mechanism 160 can be provided which includes a lock member 162 that can be inserted between two adjacent lugs 122, 124 such that the cover 106 cannot be rotated in the reverse direction 0 to open the cover 106. In one example, a single lock mechanism 160 can be provided on the cover and can be associated with a single lug 124. In one example, multiple lock mechanisms 160 may be provided, wherein each of the lock mechanisms is associated with an individual lug 124. The removal of the cover 106 from the housing body 104 is conducted in the reverse of installation, wherein the lock member 162 is removed from between the adjacent lugs 122 and the cover 106 is rotated in an opening direction 0 until the lugs 124 are aligned between the lugs 122 such that the cover 106 can be pulled from the housing body 104 in the direction B. The configuration of the lugs 122, 124 and the lock mechanism 160 are discussed in further detail in the following paragraphs.

With reference to FIGS. 9-12, it can be seen that the perimeter of each of the lugs 122 is defined by surface 122 a in addition to a side 122 b, a side 122 c, a guide surface 122 d, a nose portion 122 e, and a recessed portion 122 f. Internally, a post portion 122 h is provided between cavities 122 g and 122 i. The post portion 122 h is provided for additional structural strength while the cavities 122 g and 122 i are provided to ensure that the remaining portions of the lug 122 are of the same general thickness as the other portions of the housing body 104 to ensure that the molding and cooling process occurs in as even a manner as possible.

Each of the lugs 122 is also provided with a guide member 122 j extending from the guide surface 122 d such that a guide channel is defined between the housing body 104 and the guide member 122 j. The guide member 122 j and housing body 104 function to laterally constrain the movement of the lock member 162 to ensure that the lock member 162 travels along the guide surface 122 d as the lock member 162 is pressed downwardly in direction A.

With continued reference to FIGS. 9-10 and with reference to FIG. 13, it can be seen that each of the ramped lugs 124 has a perimeter that is defined by the engagement surface 124 a, a side 124 b, a side 124 c, and a side 124 d. An internal cavity 124 e is provided to ensure that the remaining portions of the lug 124 are of the same general thickness as the other portions of the cover 106 to ensure that the molding and cooling process occurs in as even a manner as possible. Each of the lugs 124 also has an interior face 124 f which is disposed at an angle b such that the bottom surface 124 c extends from the interior of the cover 106 (i.e. wall portion 132) a distance dl and the top surface extends a distance d2 that is greater than distance d1. This configuration is most easily viewed at FIGS. 28 to 29. In one example, the angle b is about 24 degrees and distance dl is about 4 millimeters. The disclosed construction allows the lugs 124 to have a wider diameter at the bottom surface 124 c as compared to a corresponding diameter at the top surface 124 a such that the clearance between the housing body wall 129 and the lug is greater at the bottom surface 124 c than at the top surface 124 a. This additional clearance enhances the ability of an operator to initially place the cover 106 over the housing body sidewall 129 and minimizes the need to have the cover 106 closely aligned with the housing body 104 such that the lugs 124 are able to slide over the sidewall 129 and between the lugs 122.

FIG. 13 also shows the cover 106 as having a first outer portion 130 and a second outer portion 132 having a larger diameter than the first outer portion 130. As can be seen, the lugs 124 are located on the interior side of the second portion 132. The shoulder 126 is shown as generally extending orthogonally from the second outer portion 132 towards the first outer portion 130. As stated previously, the open end 128 of the housing body 104 and the shoulder 126 are configured with similar or overlapping diameters to ensure that the open end 128 engages with the shoulder 126 to act as a stop against which the cover 106 can be no further closed onto the housing body 104. As shown, the shoulder 126 can be provided with a chamfered or rounded corner 126 a to aid in guiding the housing open end 128 onto the shoulder 126.

With reference to FIGS. 14-20, details of the lock mechanism 160 can be seen in further detail. It is noted that FIGS. 14 and 15 are drawn with portions of the cover 106 removed for the purpose of showing the function of the lock mechanism 160. FIG. 14 shows the lock mechanism 160 in an unlocked position while FIG. 15 shows the lock mechanism 160 in a locked position with the lock member 162 snapped against a lug 122 of the housing body 104. In addition to the lock member 162, the lock mechanism 160 also includes a main body 164 to which the lock member 162 is mounted. The main body 164 is shown as being a single-piece, integrally molded plastic component defining a handle portion 164 a and an insert portion 164 b. The handle portion 164 a provides for a manual grasping point for a user to manually displace the lock mechanism in direction A towards a locked position and in direction B towards an unlocked position. The insert portion 164 b is configured to be inserted into a cavity 142 of a receiving structure 140 defined within the cover 106. The cavity 142 extends from an exterior side of the cover 106, through the shoulder 126, and into the interior space defined by the cover outer portion 132. The handle portion 164 a also defines a surface 164 t that acts as a stop member against an end 146 of the receiving structure 140 such that a fully locked position of the lock mechanism 160 is defined.

In one aspect, the insert portion 164 b defines a cavity 164 c and sidewalls 164 d, 164 e, 164 f that together define a channel 164 g. Sidewall 164 d is provided with a curved profile to allow the lock member 162 to bend against the sidewall 164 d when the lock member 162 is deflected by engagement with a lug 122. This configuration reduces the point stress on the lock member 162 that would otherwise be exerted on the corner between segments 162 a and 162 b (discussed below) of the lock member 162.

The lock member 162 is provided as a bent metal wire having a first segment 162 a, a second segment 162 b disposed orthogonally to the first segment 162 a, a rounded nose portion 162 c extending at an oblique angle with respect to the second segment 162 b, and a trailing segment 162 d extending from the nose portion 162 c that adjoins a rounded portion 162 e. Although the lock member 162 is shown as being a metal wire having a circular cross-section, the lock member 162 is not limited to such a configuration. For example, the lock member 162 could have a differently shaped cross-section, such as a rectangular, square, oblong, oval, or another geometrically shaped cross-section. The lock member 162 could also be formed from materials other than a wire material. For example, the lock member 162 could be formed from a stamped sheet of metal, molded from a plastic material, or formed from a composite material. In a preferred embodiment, the lock member 162 is formed from a creep resistant material that has stress and strain properties that are generally independent of temperature variations. As such, forming the lock member 162 from a steel wire is a suitable choice. In one embodiment, the main body 164 can be overmolded onto the lock member 162. In one embodiment, the main body 164 and the lock member 162 are formed from the same material, such as a plastic material, a metal material, and/or a composite material.

To insert the lock member 162 onto the insert portion 164 b, the first segment 162 a is inserted into the cavity 164 c with the lock member second segment 162 b rotated away from the insert portion 164 b. Once inserted, the lock member 162 can be rotated about the first segment 162 a until the second segment 162 b is received into the channel 164 g. As shown, a retaining structure 164h can be provided on the insert portion 164 b such that the second segment 162 b can be received into the channel against the retaining structure 164 h when the second segment 162 b is in a relaxed, non-deflected position. The retaining structure 164 h acts to laterally constrain the lock member 162 from rotating out of the channel 164 g. Removal of the lock member 162 from the insert portion 164 b is the reverse operation.

The main body 164 is shown as also including a pair of extension members 164 i, 164 j from which catch members 164 k, 164 m respectively extend. The extension members 164 i, 164 j are deflectable with respect to the remaining portions of the main body 164. As most easily seen at FIG. 26, the receiving structure can be provided with one or more slots 144 through which the catch members 164 k, 164 m can extend. To insert the lock mechanism 160 into the receiving structure 140, the lock mechanism 160 is aligned with the cavity 142 and inserted in direction A. Initially, the catch members 164 k, 164 m will deflect inwardly against the sidewalls of the receiving structure 140, which is enabled via bending of the extension members 164 i, 164 j. As the lock mechanism 160 is further inserted into the cavity, the catch members 164 k, 164 m will snap out into the slots 144, where provided. Once this position is achieved, the lock mechanism 160 can slide within the cavity 142 in the A-B direction, but cannot be removed from the cavity 142 without manually deflecting the catch members 164 k, 164 m back through the slots 144 while pulling the lock mechanism 160 from the cavity 142.

In the example shown, a single slot 144 is provided such that extension member 164 j and catch member 164 m remain permanently deflected against a solid sidewall of the receiving structure 140. This configuration can be advantageous in that the spring force provided by the extension member 164 j can further stabilize the lock mechanism 160 within the cavity 142 and can reduce vibration.

On the opposite side of the cavity 142, the rounded portion 162 e of the lock member is constructed to continuously contact the sidewall of the cavity 142. Additionally, the cover 106 is provided with a profiled sidewall 106 a against which the lock member nose 162 c can park against when the lock mechanism 160 is in the fully unlocked position. This configuration can be advantageous in that the lock mechanism 160 can be positively held from the lugs 122 while the cover is being rotated without requiring an operator to both hold the lock mechanism 160 in the unlocked position while simultaneously attempting to rotate the cover 106.

The insert portion 164 b further includes a guide slot 164 p which slidably engages with a guide rib 148 located within the cavity 142 to prevent binding and to ensure that the lock mechanism 160 maintains proper alignment within the cavity 142 as the lock mechanism 160 is being displaced in the A and B directions. The handle portion 148 a can also include a pair of ribs 164 q, 164 r that together form a channel 164 s that receive ribs 150 to further provide for alignment of the lock mechanism 160 with respect to the cover 106 when the lock mechanism is in the closed position.

Referring back to FIGS. 14 and 15, the operation of the lugs 122, 124 and the lock mechanism 160 can be further understood. It is noted that the lug 124 located most proximate the lock mechanism 160, which is the only lug 124 shown in FIGS. 14 and 15, is provided with a shorter length than the remaining lugs 124. This configuration ensures that the lug 124 does not block the lock member 162 from fully extending past the lug 122 against which it is snapped over. As can be seen at FIG. 15, it is not possible for the lug 124 to interfere with the lock member 162.

As the lock member 162 travels in the direction A, the lock member 162 nose portion 162 c initially contacts the guide surface 122 d and is prevented from deflecting laterally off of the guide surface 122 d by the guide member 122 j on one side and by the housing body 104 on the other side. As the lock member 162 is pushed further towards direction A via handle portion 164 a, the nose portion 122 e slides along the sloped guide surface 122 d towards nose portion 122 e of the lug 122. The nose portion 162 c can deflect in such a manner due to bending in the segment 162 b of the lock member 162. Eventually, the nose portion 162 c of the lock member 162 deflects past the guide surface 122 d and over the nose portion 122 e and then snaps into the recessed portion 122 f of the lug. Once the lock mechanism 160 is in this position, the cover 106 cannot be rotated in direction 0 towards the open position due to the lock member 162 being engaged against the lug 122 while the cover 106 can also not be rotated in direction C due to the interfering engagement of the lugs 122 with the lugs 124. As such, the cover 106 is securely held onto the housing body 104 once the lock mechanism 160 has been moved to the locked position such that the lock member 162 is disposed alongside and in contact with a portion of one of the lugs 122.

The lugs 122 and the lock member 162 are shaped such the snap-in feature draws the entire lock mechanism 160 in direction A towards the lock mechanism once the lock member nose portion 162 c deflects past the lug nose portion 122 e. The spring tension in the lock member 162 holds the lock member 162 in this position by virtue of the combined forces resulting from the bending of segment 162 b and the rounded portion 162 e engaging against the side of the cavity 142 which causes bending at segment 162 d and/or nose portion 162 c. Stated in other terms, at least two portions of the lock member 162 are in a deflected state due to interaction with a lug 124 and the cavity 142, wherein the combined resulting forces from the deflected portions result in continuous spring tension on the lug 124. It is noted that the lock member 162 can be provided with a relatively small cross-sectional dimension because of this dual resistance function. In an embodiment where portions 162 d and 162 e are not provided, the lock member 162 would need to have a larger cross-sectional dimension in order to have the same locking force.

The above described bending action forces the nose portion 162 c in the direction of the recess 122 f via segment 162 d. Correspondingly, a greater force is initially required when moving the lock mechanism in direction B towards the unlocked position to snap the lock member nose portion 162 c out of the recessed portion 122 f and past the lug nose portion 122 e. As this removal force can be significant, the catch member(s) 164 k, 164 m are provided to ensure that the lock mechanism 160 stays retained within the cavity 142 and does not pop out of cavity 142 due to the resulting velocity created by the removal force once resistance from the nose portion 122 e overcome.

Referring to FIGS. 30 and 31, it can be seen that the housing and cover lug configurations are not limited to those embodiments in which both the lugs 122 and the lugs 124 have ramped engagement surfaces. Rather, either one of the lugs 122, 124 can be provided with a ramped surface while the other of the lugs 122, 124 can be provided with any other type of surfaces that engages with the ramped surface. In the particular embodiment shown at FIGS. 30 and 31, the lugs 124 are provided as previously shown and described while the lugs 122 are provided as pins extending from the housing body 104. Although the pins 122 are shown as having generally round cross-section, other shapes may be used. Referring to FIG. 31, an additional set of lugs or pins 125 may be provided such that the lock member 162 has a surface on the housing body 104 to act against in the locked position. It is noted that the lugs 124 and 125 may be formed as a single lug having the same contact surfaces for the lugs 122 and the lock member 162.

The principles described herein can be applied in a variety of filter assemblies. Examples described in which the principles applied to (air) gas filter assemblies. Examples are described include air filters and crankcase ventilation filter assemblies. The principles can be applied to a variety of alternate gas filtration arrangements, in some instances even with liquid filter assemblies.

Again, the principles, techniques, and features described herein can be applied in a variety of systems, and there is no requirement that all of the advantageous features identified be incorporated in an assembly, system or component to obtain some benefit according to the present disclosure. 

1-31. (canceled)
 32. An air cleaner assembly: a. a housing including a housing body and a removable cover that together define an interior volume for holding a filter cartridge, the removable cover being rotatable with respect to the housing body along a plane of rotation; b. a first projection located on the housing body, the first projection having a first engagement surface; c. a second projection located on the cover, the second projection having a second engagement surface, wherein one or both of the first and second engagement surfaces is a ramped surface extending at an oblique angle to the plane of rotation; and d. a lock mechanism disposed on the cover, the lock mechanism including a lock member axially movable between a locked position and an unlocked position; e. wherein the cover is positionable between a secured position and an unsecured position: i. in the secured position, the first engagement surface of the first projection being in overlapping contact with the second engagement surface of the second projection to provide resistance to the cover from being rotated in a first direction along the plane of rotation, wherein the lock member engages with a portion of the housing body to provide resistance to the cover from being rotated in a second direction opposite the first direction; ii. in the unsecured position, the lock member is removed from being alongside the first projection such that the cover can be rotated in the second direction.
 33. The air cleaner assembly of claim 32, wherein: a. the first projection is one of a first plurality of projections located on the housing body; and b. the second projection is one of a second plurality of projections located on the cover.
 34. The air cleaner assembly of claim 33, wherein each of the first plurality of projections includes a guide surface disposed at a first angle that is oblique to the plane of rotation of the cover, the guide surface being for guiding the lock member towards a first side of one of the first plurality of projections as the lock member is being displaced between two of the first plurality of projections.
 35. The air cleaner assembly of claim 34, wherein each of the first plurality of projections includes a guide member extending from the guide surface, the guide member constraining the movement of the lock member along the guide surface.
 36. The air cleaner assembly of claim 34, wherein the first angle is about 10 degrees.
 37. The air cleaner assembly of claim 32, wherein the lock mechanism includes a main body to which the lock member is secured.
 38. The air cleaner assembly of claim 32, wherein the cover includes a sidewall configured as a parking location for the lock member that frictionally retains the lock mechanism in the unlocked position.
 39. The air cleaner assembly of claim 33, wherein each of the first plurality of projections includes a recessed portion and wherein the lock member includes a nose portion that snaps into the recessed portion when the lock mechanism is moved to the locked position.
 40. The air cleaner assembly of claim 32 wherein only a single first projection is provided on the housing body and only a single second projection is provided on the cover.
 41. The air cleaner assembly of claim 32, wherein only a single first projection is provided on the housing body.
 42. The air cleaner assembly of claim 32, wherein only a single second projection is provided on the cover.
 43. The air cleaner assembly of claim 41, wherein a plurality of radially spaced second projections are provided on the cover.
 44. The air cleaner assembly of claim 42, wherein a plurality of radially spaced first projections are provided on the housing body.
 45. The air cleaner assembly of claim 32, wherein a plurality of radially spaced first projections are provided on the housing body and a plurality of radially spaced second projections are provided on the cover.
 46. The air cleaner assembly of claim 32, wherein the portion of the housing body is the first projection.
 47. The air cleaner assembly of claim 32, wherein the portion of the housing body is a third projection associated with the housing body.
 48. The air cleaner assembly of claim 32, wherein the first projection is a lug defining the first engagement surface and the ramped surface.
 49. The air cleaner assembly of claim 32, wherein the second projection is a lug defining the second engagement surface and the ramped surface. 